Why (LDL particle) size matters.

Having gone through the math(s) with several people, I thought I'd stick it in a blog post for posterity.

I know that this is a diagram of a chylomicron, but bear with me!

Cholesterol synthesised in the liver is exported in LDL particles. The more cholesterol that's synthesised, the more particles there need to be to carry it.

∴ LDL-P (particle number) ∝ LDL-C (total amount of cholesterol)

The particles are roughly spherical with a very thin wall (consisting of a phospholipid mono-layer, the yellow wiggly lines with a green end bit in the above diagram).

Volume of a sphere = 4/3 * π * r³, where r = half the diameter.

If there's a 10% reduction in LDL particle size, the volume reduces to 0.729, relative to the original size. Therefore, to carry the same amount of cholesterol requires 1/0.729 = 1.37 times more particles, which is a 37% increase in the number of LDL particles, relative to the original size.

∴ LDL-P (particle number) ∝ 1/LDLsize³

As it's LDL particle number that determines the infiltration of LDL cholesterol into the media of artery walls, it's advisable to keep cholesterol synthesis to a minimum by keeping fat intake to a reasonable level * (i.e. not Nutritional Ketosis level) and keeping LDL particle size to a maximum by keeping sugars & fast starches intake to a reasonable level*.

Before someone asks, what I mean by a reasonable level is a level that is burned by the body without having a chronic excess. An acute excess can be stored, provided that mean intake is less than mean burning.

How COULD I write a post about LDL-P and forget to include THIS?

Another tasty analogy.

Here's a tasty analogy.

From http://grannychoe.com/recipe3_Soup.php

In Ultra-high-fat (~80%) diets: Fat storage, and a delicious analogy, I analogised the effect of carbohydrate consumption on mean serum glucose level with the effect of fat consumption on mean serum triglyceride level. Here's another one.

Chronic excessive consumption of carbohydrates relative to what are being burned results in excessive fat synthesis in the liver, resulting in excessively-high fasting serum triglyceride level, which is harmful.

Chronic excessive consumption of fats relative to what are being burned results in excessive cholesterol synthesis in the liver, resulting in excessively-high fasting VLDL, LDL & IDL level, which is harmful.

Seems legit.

Lipoproteins & apolipoproteins: E, by 'eck.

In December 2008, I wrote about Cholesterol And Coronary Heart Disease , where I used a limousine metaphor to describe how cholesterol & fat are transported around the body. Here's a diagram of a chylomicron lipoprotein "limousine". Chylomicrons transport dietary fat (triglycerides) & cholesterol from the gut to the liver & other tissues. As there's much more dietary fat than dietary cholesterol, the contents are mostly fat.

A chylomicron. T=Triglyceride C=Cholesterol. From http://en.wikipedia.org/wiki/Lipoprotein

The lipoprotein "limousines" vary a lot in size.

(a) VLDL (b) chylomicrons (c) LDL (d) HDL. 
From http://healthcorrelator.blogspot.co.uk/2011/11/triglycerides-vldl-and-industrial.html

Apolipoproteins are the "chauffeurs" which determine to where lipoproteins transport stuff.
Apo A is found mainly on HDL, which transports fat & cholesterol from tissues to the liver.
Apo B is found mainly on LDL, which transports cholesterol from the liver to tissues.
Apo C is found on HDL when fasted, but moves to chylomicrons & VLDL when fat is eaten.
Apo D is found mainly on HDL and is is associated with an enzyme involved in lipoprotein metabolism.
Apo E is found mainly on chylomicrons & IDL and transports lipoproteins, fat-soluble vitamins, and cholesterol into the lymph system and into the blood. In the CNS, Apo E transports cholesterol to neurons. Defects in Apo E result in hyperlipidaemia , cardiovascular & neurological diseases, and is the E referred to in the title.

There's also Apo H, which is a β-glycoprotein involved in the binding of cardiolipin. It has nothing to do with the above lipoproteins.